Climate change: possible macroeconomic implications

Quarterly Bulletin 2022 Q4

Published on 21 October 2022

By Marilena Angeli, Cassandra Archer, Sandra Batten, Ambrogio Cesa-Bianchi, Lucio D’Aguanno, Alex Haberis, Theresa Löber, Sarah Maxwell, Rana Sajedi, Michelle van der Merwe, Boromeus Wanengkirtyo and Chris Young from the Bank’s Climate Hub, International Directorate, Monetary Analysis Directorate and Research Hub.^{footnote [1]}

Summary

Climate change – and the response of governments at home and abroad to it – will affect the macroeconomy in a number of ways, both over shorter horizons and the longer term. Since it influences key economic variables such as output and inflation, climate could change matter for monetary policy makers such as the Monetary Policy Committee (MPC). Monetary policy clearly cannot solve climate change, but climate change may have macroeconomic implications that could be relevant for monetary policy makers. This article explores the macroeconomic effects of physical impacts from climate change (such as extreme weather) and the transition to a net-zero economy (such as through less carbon intensive investment), with a particular focus on the UK economy. It considers what the longer-term changes associated with climate change might mean for the macroeconomic landscape within which monetary policy operates. It also provides an initial assessment of some possible monetary policy considerations. Many of the questions in this area are new, open and worthy of further research. That reflects new analytical challenges associated with climate change, including related to macroeconomic modelling and data quality and availability. In addition, there are many dimensions of uncertainty, not least in relation to how the physical effects of climate change and governments’ policy responses to it evolve over the coming years and decades.

1: Introduction

In the UK, the MPC sets monetary policy to meet HM Government’s 2% inflation target, and, subject to that, to support the economic policy of the Government, including its objectives for growth and employment.

In response to macroeconomic developments in the UK, including spillovers from the rest of the world, the MPC adjusts its policy instruments in order to meet the 2% inflation target. The two main policy actions that the MPC can take are to change the interest rate that the Bank of England charges commercial banks to borrow (‘Bank Rate’) and to change the stock of assets that the Bank holds on its balance sheet as a result of outright purchases (‘quantitative easing/tightening’).

When assessing the outlook, the MPC typically looks at how the economy is likely to develop over the next two to three years, the horizon over which monetary policy can sustainably bring inflation back to target. Unanticipated economic events, often called ‘shocks’, will affect the outlook for the economy over that period, sometimes materially; the sharp and significant rise in wholesale and domestic energy prices since Russia’s invasion of Ukraine is a recent example. The MPC also monitors and assesses longer-term, and sometimes more gradual, developments to understand structural economic changes that are happening in the economy over a number of years. An example here is the increased integration of emerging economies into the world economy along a number of dimensions from the early-2000s, sometimes called ‘globalisation’, which for a sustained period reduced the prices of manufactured goods imported by advanced economies.

In some sense, climate change comprises another set of economic shocks and structural changes for monetary policy makers to assess and monitor in order to achieve the inflation target. However, climate change presents new challenges to monetary policy makers in a number of respects, including its global dimension, its very long time horizon and the degree of uncertainty about both climate policy and how economic agents will respond. That is particularly so given the non-linear nature of climate change leading to irreversible effects (‘tipping points').

Physical impacts from climate change, and governments’ policy responses to climate change such as to support the transition to a net-zero economy, have the potential to impact the macroeconomy in numerous ways. They are likely to influence key economic variables such as output and inflation, which in turn are directly relevant to the decisions taken by the MPC. For instance, increased severity and/or frequency of extreme weather events at home and abroad could lead to supply disruptions and a rise in some prices, including of food. Moreover, over the coming years and decades, UK legislation to achieve net-zero emissions by 2050 (Climate Change Act 2008, amended in 2019) requires ambitious changes across all parts of the economy, from power generation to transport to how we heat and build our homes.

Monetary policy clearly cannot solve climate change, but climate change may have macroeconomic implications that could be relevant for monetary policy makers. This implies that the greatest contribution monetary policy can make to facilitate the transition to the green economy is to secure price stability and maintain the credibility of the monetary regime through the transition.

This article explores how the physical impacts from climate change and the transition to net zero might impact the economy and so could matter for monetary policy. It first explores the macroeconomic effects of physical and transition impacts, with a particular focus on the UK economy (Section 2). Section 3 then considers what the longer-term changes associated with climate might mean for the macroeconomic landscape within which monetary policy operates. Section 4 provides an initial assessment of some possible monetary policy considerations, before Section 5 concludes.

The article provides a complement to the extensive body of work in recent years by the Bank of England and other institutions focused on understanding the financial risks from climate change and the transition to a net-zero economy.^{footnote [2]} It also contributes to recent debates – including in the economic literature, the Network of Central Banks and Supervisors for Greening the Financial System (NGFS) and Bank research^{footnote [3]} – on the potential impacts of climate change on the macroeconomy and the implications for monetary policy. For example, recent years have seen speeches by senior officials from, among others, the Federal Reserve (Brainard (2019)), the European Central Bank (Lane (2022); Schnabel (2022)), the Bank of England (Bailey (2021)) and the Reserve Bank of Australia (Debelle (2019)). It is worth noting at the outset that many of the questions in this area are new, open and worthy of further research. That reflects new analytical challenges associated with climate change, including related to macroeconomic modelling and data quality and availability. In addition, there are many dimensions of uncertainty, not least in relation to how the physical effects of climate change and governments’ policy responses to it evolve over the coming years and decades.

2: Effects on macroeconomic fluctuations

Physical impacts

Physical impacts from climate change have the potential to impact the macroeconomy in numerous ways, influencing key economic variables such as output and inflation.

The physical impacts of climate change stem from both the increased frequency and severity of acute weather events like flooding, extreme temperatures and windstorms, and gradual or chronic changes in the climate, such as those associated with gradually rising temperatures and sea levels. The impacts associated with both acute and chronic changes transmit through many channels, affecting both the supply and demand sides of the macroeconomy. In this section, we explore the macroeconomic effects of the physical impacts associated with climate change with a particular focus on the experience of the UK economy and drawing on international evidence from countries who may have experienced more severe events than typically found in the UK. In terms of the response of monetary policy to these physical impacts, a key challenge is to assess the macroeconomic effects over the next two to three years, the horizon over which monetary policy can sustainably bring inflation back to target.

This section next discusses the different channels of physical effects on economic growth, inflation, as well as gradual changes and global spillovers.

Effects of extreme weather on economic growth

The economic literature shows that extreme weather events tend to have a predominantly negative effect on economic growth, in some cases up to several years. Reasons include damage to the economy’s stock of physical and infrastructure capital, the impact on the labour force (including through displacement or migration) or losses in productivity (due to breaking supply linkages, for instance).

As a proxy for possible physical effects of climate change, we can look at natural disasters. Their effect on economic growth is mixed (Cavallo and Noy (2009)). Using data on natural disasters since 1900, Raddatz (2009) estimates natural disasters persistently reduce real GDP per capita by at least 0.6% in a panel of countries. However, this covers a wide range of natural disasters and is an average effect: the impact tends to be smaller for wealthier countries (Botzen et al (2019); Noy (2009)) particularly in those cases where the events are sufficiently insured (von Peter et al (2012)). In contrast, Loayza et al (2012) observe that after earthquakes and storms there are positive growth effects which are attributed to reconstruction of infrastructure and capital. However, severe disasters tend to put economies on slower growth paths. Hsiang and Jina (2014) find that national incomes fall and do not recover within the first twenty years following a cyclone. Clearly there are limits to which we can extrapolate from these studies for climate change, not least because changes in the climate are not linear, but the likely increase in frequency and severity of extreme weather events means such effects may be bigger in the future. Box A looks at flooding and UK house prices as a case study.

Effects of extreme weather on inflation

Extreme weather events can also affect inflation, at least temporarily. Heinen et al (2019) study the impact of hurricanes and floods on the monthly inflation rates of 15 Caribbean islands. They conclude that although the average inflation impact of hurricanes is small, it can be greater for more severe events. Similarly, Cavallo et al (2014) find that even with the severe supply disruptions that major earthquakes can bring, prices remain stable. They attribute it to retailers avoiding perceptions of price-gouging, ie preferring to run out of stock in response to a supply disruption, rather than increase prices. Parker (2018) finds that droughts seem to be the only type of natural disaster with an impact on headline inflation which persists for a number of years, with food prices a key channel. Peersman (2022) shows that exogenous (weather-driven) food price shocks have a strong impact on consumer prices in the euro area, suggesting that inflation volatility in advanced economies may rise with an increased frequency of global extreme weather events. Taken together, these factors suggest it is likely that inflation may become more volatile, particularly in geographies subject to more frequent extreme weather events.

While physical impacts of climate change have been shown to temporarily raise inflation, in particular food prices, such effects have tended to dissipate in the medium term. As noted above, however, the impacts of such events may be greater in the future if extreme weather events are more frequent and more severe.

Gradual changes in the climate system: macroeconomic effects

Physical impacts from climate change may also reflect chronic changes in the climate system, such as those associated with a gradual rise in average global temperatures. This causes an increase in the frequency and intensity of weather-related natural disasters as previously discussed. For example, global warming is associated with a slowdown in warm-water currents in the Atlantic Ocean, which in turn leads to changing heavy precipitation patterns in the tropics and Europe, and stronger storms in the North Atlantic (IPCC (2021)). However, the gradual rise in itself could cause negative effects on economic growth, both in the short and long run, driven by a range of factors, including reduced labour productivity, slower human capital accumulation, diminished human health and political instability (Dell et al (2012)).The negative economic effects from gradual temperature rises can increase in a non-linear way as the temperature deviations from historical norms get larger (Felbermayr et al (2014); Burke et al (2015)). Moreover, most of the effects appear larger in emerging economies, with more extreme temperature variations and institutional factors creating challenges to adaptation.

The UK’s infamously cloudy – but moderate – weather makes it somewhat less likely to be significantly directly exposed to gradual changes. For example, the University of Notre Dame Global Adaptation Index ranks the UK fifth (out 182 countries) least vulnerable to physical impacts of climate change. While the UK is somewhat less directly affected by physical risk compared with other low-lying countries, for example, Box C explores the different channels by which the economic effects of physical (and transition) impacts can transmit across countries.

Gradual warming and extreme weather events have a negative impact on GDP, although there may be a temporary boost from reconstruction. Physical impacts of climate change appear to temporarily raise inflation, in particular food prices, but such effects have tended to dissipate in the medium term in past data. These weather events may largely be the same as in previous decades, although their likely size and frequency may be greater, such that impacts could become more pronounced.
Insofar as there are more and larger weather events that may require a more active role for monetary policy. However, some of these effects may be more evident over relatively short horizons, whereas monetary policy can sustainably return inflation back to target over the next two to three years. But as discussed in Section 3, gradual warming and increasing frequency of extreme weather events may have an important influence in the economy in the long run, such as via uncertainty, investment and trend productivity growth.

Transition impacts

As the economy adjusts to a low-carbon and ultimately a net-zero economy, there are a number of transition impacts on the macroeconomy that arise out of the process of adjusting policies, preferences and technology. These impacts can be orderly, leading to a ‘smooth transition’, whereas a ‘disruptive transition’ may induce amplified effects on the economy through the various channels discussed here. This section explores what we can learn about the macroeconomic effects associated with the adjustment of the UK economy toward net zero, as in Section 2, drawing on UK evidence as well as lessons from abroad. An important caveat is that most of the economic literature on transition risks examine market-based climate policy mechanisms that have been introduced over the past decade or so. But many other climate policies will need to be deployed to deliver the transition to net zero, of which we have much less understanding. The first and second parts of this section focus on mitigation policies and their role in changing prices faced by households and companies in the economy, which is in turn likely to generate a reallocation of activity between sectors of the economy towards those that are less carbon intensive. The third part looks the role of expectations, including the role of uncertainty, in the transition to net zero.

The macroeconomic impacts of mitigation policies

Governments over recent years in many countries have introduced a range of policies to lessen the impacts of climate change by preventing or reducing the emission of greenhouse gases (de Silva and Tenreyro (2022)), as well as measures to adapt to the effects of climate change. These can be grouped into three broad categories. First, there are economic incentives, such as carbon taxes, emission trading schemes, and subsidies for investing in research and development (R&D), adopting green technology, and using clean energy. Second, there are regulations, such as bans on coal usage, or production and mandatory technology requirements. Third, there are institutional approaches, such as voluntary industry standards for climate disclosures. The introduction of mitigation policies by governments, and the pace at which they are strengthened, are likely to have effects both on the demand and supply side of the economy.

Some mitigation policies, including subsidies and direct regulations, encourage cleaner forms of energy production or reduce energy consumption by households or firms. One example is green energy subsidies to encourage greater use of renewables such as wind power. These policies lower the overall cost of renewable energy provided to power grids and, over time, reduce the average cost of this form of energy provided to firms and households, which may lower inflation (although energy prices do not always reflect average production costs across all sources of energy). The overall effect on the economy’s productive capacity and aggregate demand is more ambiguous, however. It depends in part on how the subsidies were financed – in particular, whether and what type of tax increases would be required, or the diversion of other types of government spending.

On the other hand, policies that subsidise research and development into green technologies are more likely to boost the economy’s productivity and growth. Its impact on inflation would depend on the balance between the relative effects on supply and demand, which could vary at different horizons.

There could also be various regulatory initiatives to discourage carbon-intensive production or simply enforce lower carbon inputs into production. The economic literature on this is limited, but such regulatory initiatives may raise costs and consumer prices, at least in the short run.

The relative effects of late or early action on carbon prices. Late action showing lower prices to start with but higher later, with early action the opposite.

Source: Bank of England Climate Biennial Exploratory Scenario (CBES).

Another potentially important tool in the transition to net zero is carbon pricing. By charging for greenhouse gases emissions, the policy puts a price on emissions and also encourages investments into energy-efficiency improvements. The price can be determined through a range of ways, for example, via market mechanisms (such as the UK and EU Emissions Trading Schemes (ETS) in which governments sets the maximum amount of emissions), directly though taxation or via policies such as standards and regulations. The UK uses a combination of the carbon cap-and-trade (UK ETS) and various carbon taxes – direct taxes such as the Climate Change Levy and the Carbon Price Support, and indirect carbon taxes, such as fuel duties.

Given there are many examples of carbon-pricing schemes that have been active for some time, such as those in the EU and Canada, there are a number of attempts in the economic literature to assess the macroeconomic effects of these policies. Overall, the impacts depend crucially on the design of the mitigation policies, including the extent to which and how any revenues from the policy are used by the fiscal authority (for example, by reducing other taxes, increasing subsidies or raising government spending). Fiscal policy tools can support activity and help to offset some of the negative direct impacts on output from carbon pricing if the revenues raised from the carbon tax are recycled back to households and firms (Yamazaki (2017)).

There are two typical empirical findings, although results in this literature are mixed rather than definitive. First, a reduction in the quantity of carbon credits and allowing market mechanisms to dictate carbon prices raises inflation and reduces economic growth (Kaenzig (2022)). Second, in contrast, several studies show setting a carbon price directly through carbon taxes has a broadly neutral impact on inflation and output, although as discussed below these results are based on a low level of carbon prices.^{footnote [4]}

There are at least two reasons to explain the different impacts on inflation. First, as carbon taxes set a path for the carbon price directly (in contrast to an ETS, under which prices could be more volatile), firms can plan ahead to a greater degree – for example, in managing other costs and investing in green technologies. Second, Konradt and Weder di Mauro (2022) suggest carbon taxes may have a disproportionate impact on low-income households, given their consumption baskets are more energy intensive. That could reduce their demand, offsetting the initial inflationary impact of the carbon tax.

But an important caveat and reason why the estimated empirical effects tend to be small is that the historical carbon prices on which these studies have been based have been and still currently are low. Konradt and Weder di Mauro (2022) document that the majority of taxes in Europe and Canada are below US$30 per tonne as of 2018, with some as low as US$0.08.^{footnote [5]} Estimates of the potential paths carbon prices would need to take in order to meet net-zero targets indicate a substantial rise in carbon prices from their current levels. One such estimate is from the Bank of England’s Climate Biennial Exploratory Scenario (CBES), which simulates a substantial increase in carbon prices, rising from US$30 as at end-2020 to US$900 per tonne of carbon dioxide equivalent (in 2010 dollars) by 2050 under an ‘Early Action’ scenario (Chart 1). If policy action is delayed (‘Late Action’), carbon prices remain at US$30 until 2030 but the simulated increase is more abrupt and results in a higher carbon price in the later years (over US$1,000 by 2050).

Therefore, the macroeconomic effects of past carbon-pricing schemes may not be a good guide to the macroeconomic effects of future carbon-pricing schemes’ rises. Structural modelling can also complement empirical analysis and help us understand the potential effects of future carbon price increases. The IMF’s October 2022 World Economic Outlook has a chapter that finds limited inflationary impacts of carbon-pricing initiatives. However, there are a number of quite specific assumptions in the baseline model, in particular firms and households are very forward looking and mitigation policies are known with certainty. In response to the anticipated rise in energy prices, firms and households in the model cut investment and consumption – reducing aggregate demand that offsets the inflationary impacts of the carbon taxes. It is also worth noting that this model only simulates a 25% reduction in emissions.

It will be important for central banks to understand the expected macroeconomic effects of different mitigation policies, particularly on inflation, in order to set monetary policy. Section 4 provides an initial assessment of some possible monetary policy considerations.

Investment and economic activity across sectors during the transition in the UK

One important feature of the transition that monetary policy will need to monitor is its effect on investment in less carbon intensive capital, sometimes called ‘green investment’ (such as investments into low-carbon energy like wind turbines, or into energy-efficient infrastructure like electric vehicles). Meeting the net-zero targets will require investments in energy and transport infrastructure alone to more than double from current levels over the next decade and thereafter maintain that level until 2050 (Lenaerts et al (2021)). The International Energy Agency’s (IEA (2021)) pathway to net zero highlights that current energy investment is US$2 trillion (2.5% of global GDP) but needs to rise to almost US$5 trillion to meet net-zero targets. The World Energy Investment report (IEA (2022)) finds that global clean energy spending had remained flat for several years, but it has been increasing since 2021. If this is sustained, it could lead to an overall increase in global investment, and thus boost demand, though the rise in green investment may be partially offset by a fall in more carbon-intensive investment.

To understand how the transition towards greener activities is affecting economic activity, the Bank of England asks firms directly through its Agency network, as well as the Decision Maker Panel (DMP) survey.^{footnote [6]} Reports from the Agents over the first half of 2022 suggest firms that supply goods and services for the net-zero transition – such as those supplying wind power or heat insulation – have continued to experience strong growth in demand. This reflects how investment intentions will vary by sector, based on a sector’s role in supporting the transition, as well as their existing carbon intensity (and therefore the extent to which they need to decarbonise). See Box B for the sectoral effects in the Climate Change Committee’s (2020) Balanced Net Zero Pathway.

Similarly, the DMP survey in September and October 2021 suggested 44% of UK firms intend to increase climate-related investments over the next three years (Chart 2).^{footnote [7]} We can map this to each sectors’ importance in the UK economy using their Gross Value Added (GVA), which measures the value of each sector’s production. The DMP shows that some sectors with relatively large GVA shares – like the wholesale and retail and manufacturing sectors – currently plan to strongly increase climate-related investments over the next three years, while for other sectors their investment plans related to climate and the transition are comparatively modest (Chart 3). The Office for National Statistics’ Business Insights and Conditions Survey (BICS) suggests a majority of firms have started to take action to reduce carbon emissions, although a smaller proportion explicitly monitor climate-related risks and have a climate strategy (Chart 4).^{footnote [8]}

How much UK firms intend to increase climate-related investments over the next three years.

Sources: DMP survey and Bank calculations.

How different sectors plan to increase climate change-related spending over the next three years compared to their GVA.

Sources: DMP survey and Bank calculations.
(a) Sectoral GVA shares are 1998–2019 averages.

ONS findings showing that a majority of firms have started to take action to reduce carbon emissions.

Source: Office for National Statistics.

Expectations and uncertainty effects

The transition to net zero will be a long-run process, with many changes in the structure of the economy due to occur into the future. However, economic behaviour and asset prices are also driven by forward-looking expectations and so affect monetary policy.

Investments into green technologies often have a long horizon and are particularly susceptible to increased uncertainty. This includes general macroeconomic uncertainty, but also climate policy uncertainty (IEA (2017); Fried et al (2021)). Much like how individuals can postpone deciding on a weekend’s activities until they see a more accurate weather forecast closer to the date, an increase in uncertainty induces firms to delay investments, particularly those with long payback periods. The (negative) effect on aggregate demand and economic growth by increased uncertainty is well documented (Leduc and Liu (2016); Basu and Bundick (2017)). A previous Quarterly Bulletin article showed how a rise in uncertainty – then associated with the UK’s exit from the EU and the Covid pandemic – dampened UK business investment (Bunn et al (2021)).

The extent to which different sectors rate climate change policy as a main source of uncertainty.

Sources: DMP Survey and Bank calculations.
(a) Sectoral GVA shares are 1998–2019 averages.

The DMP survey shows some UK firms have already begun citing climate change policy as one of their main sources of overall uncertainty (Chart 5). This is particularly apparent in sectors affected by climate change, such as transportation and real estate. This suggests a clear and orderly path of climate policy during the transition that avoids inducing uncertainty would encourage higher levels of private investment.

Inflation expectations are another example of how expectations about the future can affect current economic decisions. If firms reprice their products infrequently, they must set prices in advance to anticipate their future demand and costs. Therefore, news about higher future costs – for example, from a continued rise in carbon prices, such as in the CBES scenario – could lead to higher inflation in the near future. Inflation expectations could also ‘propagate’ shocks to firms’ costs arising from carbon prices: making the inflationary impacts longer lasting that the direct impact of the initial shock (Coibion and Gorodnichenko (2015)), though its quantitative importance is uncertain (Wong (2015)). If increases in carbon prices are inflationary, these could lead to ‘second-round effects’ – leading into higher inflation expectations, and consequently, to more inflation later on. Moreover, increases in carbon taxes may be announced and so anticipated a number of years in advance. By contrast, standard economic shocks are unexpected and can arise in either direction. As a result, further analysis is required to better understand how carbon price changes may affect inflation, inflation expectations and economic activity. Monetary policy plays an important role here, and a credible monetary regime that anchors inflation expectations would help minimise the potential inflationary impact. The monetary policy implications are further discussed in Section 4.

Most of the economic literature on transition impacts examine market-based climate policy mechanisms that have been introduced over the past decade or so. But many other climate policies will need to be deployed to deliver the transition to net zero, of which we have much less understanding. Additionally, relative to a smooth transition, a disruptive transition may induce amplified effects on the economy through the various channels discussed here, and potentially others too. A credible path for future policy for the transition is vital to reduce uncertainty and enable economic agents to react smoothly and appropriately.
Some initial findings are that climate policies that encourage the transition to net zero are likely to have both supply and demand effects on the macroeconomy, though it depends on institutional factors, such as the climate policy mix and how carbon tax revenues are used by the government.^{footnote [9]} The estimated empirical effects tend to be small but that could be simply because historical carbon prices on which these studies have been based on are currently low; prices will need to rise significantly from their current levels to be consistent with net-zero targets.
A survey of UK companies shows that 44% of firms plan to increase capital expenditure in response to climate change, about a third of these by 10% or more. This is consistent with net-zero scenarios of sharply increased investment. This increase is highly uneven across sectors in the economy, with some planning to invest much more than others.

Box A: Case study – flooding and house prices in the UK

In the UK, one key manifestation of extreme weather events is flooding. For example, during the 2013–14 winter many parts of the UK were affected by both inland and coastal floods (Spencer et al (2015)). Looking ahead, the UK Climate Change Risk Assessment 2022 rates the adverse impact by the 2050s to ‘people, communities and buildings’ from river and surface flooding as ‘very high’ (consistent with economic damages or forgone opportunities costing over £1 billion per annum), and from coastal flooding as ‘high’ (costing over hundreds of millions of pounds per annum). It also rates risks to ‘business sites’ from flooding as ‘very high’, and to ‘infrastructure networks’ as ‘high to very high’.

One direct effect after flooding is the revaluation of properties: Garbarino and Guin (2021) found that the sale price of flooded UK residential houses fell by 4.2% in response to the 2013–14 floods, relative to equivalent non-flooded properties. Similar impacts have also been experienced abroad; for instance, Beltrán et al (2018) estimated the value of flooded inland properties in the United States, associated with a location in the 100-year floodplain, declined by 4.6%.

Lower house prices in turn can reduce household consumption. One channel is via a wealth effect, ie households consuming less in reflection of their lower wealth. For the UK economy estimates of these effects tend to be quite small (Fernandez-Corugedo et al (2003); Attanasio et al (2008)). Lower house prices also reduce the value of households’ collateral for loans. Cloyne et al (2019) find significant effects of house prices on borrowing and hence consumption. They find that homeowners with lower levels of collateral borrow much more against house price increases than do those with higher levels of collateral. This is one example of how financial frictions can propagate the initial economic shock arising from physical impacts, which is explored more in Box C.

In the Bank of England’s Climate Biennial Exploratory Scenario (CBES), most of the increase in projected average annual losses in UK general insurers arise from flooding, and it finds the impact on their solvency positions is likely to be manageable. However, the CBES also highlights that insurance on some properties, especially under the ‘No Additional Action’ scenario, would become unaffordable once the Flood Re scheme ends.^{footnote [10]}

Box B: The Balanced Net Zero Pathway (Climate Change Committee, 2020)

One illustration of the different sectoral impacts of the transition to net zero can be seen in the Climate Change Committee (2020) Balanced Net Zero Pathway. For example, the electricity generation sector is a large source of UK carbon emissions (15% of 2018 emissions), and they estimate that to reach net-zero targets, the sector will need to reallocate away from using fossil fuels towards cleaner sources of energy generation (Chart A).^{footnote [11]} At the same time, Chart A also shows it has to invest into more than doubling its output by 2050 to support the transition of other sectors. This includes the electrification of the surface transport sector, which has to implement an 83% reduction in emissions from 2019 levels by 2035, in order to meet net-zero targets (Chart B).

The changes in the energy mix needed to reach net zero targets with Fossil Fuels leaving the mix in favour of other fuel types.

Source: Climate Change Committee (2020).

The changes needed emissions for various sectors to meet their 2035 Net Zero targets.

Source: Climate Change Committee (2020).

Box C: Amplification channels and international spillovers

The UK has been, and is expected to be, less directly exposed to the physical impacts associated with climate change compared to other countries. However, as an open economy engaged in the production and global trade of goods and services, it can still be affected by the impacts – both related to physical and transition effects – taking place in other economies through what are referred to as international spillovers. In this Box, we explore spillovers associated with both physical and transition impacts. Financial frictions are well known to be able to amplify and propagate various macroeconomic shocks (domestically and internationally), perhaps illustrated most clearly in the 2008–09 financial crisis.^{footnote [12]} Less is currently understood about other channels, such as mass migration, although looking forward these may increasingly act as spillovers.

With global trade having evolved in recent decades into a ‘global value chains’ (GVCs) model, whereby the production chain for goods and services is located across multiple borders, extreme weather events in one country that result in supply disruptions and/or changes in climate policies can create spillover macroeconomic effects in many others because of the way that production is as concentrated in a few central ‘hubs’. Carvalho et al (2021) found a key role for production networks in the propagation of the initial shock from the 2011 Japanese earthquake upstream and downstream along supply chains. Commodity markets – in particular, food and energy – could also transmit physical risk shocks across boundaries because of their highly traded nature. Peersman (2022) estimated that international food supply shocks (driven by droughts and harvest failures) already explain 30% of euro-area inflation volatility between 1961 and 2016. By contrast for intermediate and finished goods, GVCs offer diversification among foreign suppliers which can lower volatility, by lowering the exposure to any single country (including domestic suppliers) (D’Aguanno et al (2021)).

Transition impacts can directly affect financial sector balance sheets, for example through stranded assets that become unviable because of their incompatibility with carbon-neutral activities (NGFS (2019a), (2019b)). Similarly, damages to the capital stock from physical impacts can affect valuations of asset holdings by firms, households and could also transmit to the financial sector. This capital destruction (by flooding, for example) can lead to an increase in loan defaults from the inability of households and firms to repay, which ultimately generates losses at banks. This impairs the health of banks (a reduction in bank capital), which in turn can reduce their ability to lend to the real economy (Gambacorta and Mistrulli (2004)). The climate-induced losses reduce the ability of firms and households to borrow, and thus their capacity to invest and consume – in the economics literature, this is known as a financial accelerator mechanism.

These financial accelerator channels can cause economic contractions and have historically played an important role in business cycles (Gilchrist and Zakrajšek (2012); Christiano et al (2014)). Contacts from the Bank’s Agency network indicate that there remains a risk of adjustment in the valuations of carbon-intensive assets, such as commercial diesel vehicles, but the scale and speed is uncertain. These shocks could also transmit internationally, particularly in countries like the UK with internationally integrated financial and credit markets. Cesa-Bianchi and Sokol (2022) provide evidence that adverse financial shocks in the US transmit to a tightening in credit conditions and slower economic activity in the UK.

3: Effects on the long-run equilibrium interest rate, R*

While monetary policy is typically focused on responding to cyclical shocks, it does so within a broader macroeconomic landscape, which is shaped by a number of slow-moving structural factors (Bailey (2022)). Given the potentially permanent effects on the environment, physical climate-related events will impact economic factors such as risk and productivity in the long run. Furthermore, given the scale and duration of the necessary adjustment, the transition to net zero requires a large structural economic change, with consequences particularly for the future path of investment. Therefore, in addition to the impacts discussed in the previous section, both the physical impacts from climate change and the transition to net zero are likely to significantly shape the longer-term macroeconomic landscape within which monetary policy operates.

Economists use a number of so-called ‘equilibrium’ concepts to summarise the macroeconomic landscape, and therefore the policy-relevant impact of structural changes in the economy. One such concept, which is of particular importance to monetary policy, is the ‘equilibrium real interest rate’ – defined as the real interest rate (ie the interest rate adjusted to remove the effect of inflation) that sustains the actual output level of the economy in line with its potential and inflation at target. As such, the equilibrium real interest rate can act as a guide to monetary policy over the medium to long run. Long-run structural changes in the economy, like those implied by climate change and policies, affect the long-run trend in the equilibrium real interest rate, which we refer to as R*.

The determinants of R*

In an organising theoretical framework for understanding its determinants, R* is also the price that brings the demand and supply for capital into balance (see Bailey et al (2022)), for a more complete exposition). The demand for capital arises from firms that want to invest in capital for production.^{footnote [13]} The supply of capital is from households accumulating wealth, and who put this wealth into capital by (directly or indirectly) holding corporate shares or bonds, and government bonds. Within this framework, R* is the risk-free rate of return on government bonds, and, in equilibrium, it is equal to the return to an additional unit of capital minus the ‘risk premium’, which compensates households for the volatility in the return to capital.

Importantly, for an open economy like the UK, R* will be determined on the global capital market, because frictions that impede the free international movement of capital are weaker at this longer-term horizon. In other words, structural factors that determine the global supply and demand for capital will pin down a ‘Global R*’, and it is this concept of R* which acts as a long-term anchor for the UK's domestic equilibrium real interest rate (Cesa-Bianchi et al (2022)).

There are a large number of potential channels through which both physical impacts from climate change and the (global) transition to net zero may affect the long-run trend equilibrium interest rate, R*. Some forces could put upward pressure on R*, such as an increase in trend productivity growth or additional green investment. Other forces could work in the opposite direction, such as an increase in the risk premium.